An evaluation of Deccan Traps eruption rates using geochronologic data

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS Geochronology Pub Date : 2021-04-16 DOI:10.5194/gchron-3-181-2021
B. Schoene, M. Eddy, C. Keller, K. Samperton
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引用次数: 24

Abstract

Abstract. Recent attempts to establish the eruptive history of the Deccan Traps large igneous province have used both U−Pb (Schoene et al., 2019) and 40Ar/39Ar (Sprain et al., 2019) geochronology. Both of these studies report dates with high precision and unprecedented coverage for a large igneous province and agree that the main phase of eruptions began near the C30n–C29r magnetic reversal and waned shortly after the C29r–C29n reversal, totaling ∼ 700–800 kyr duration. These datasets can be analyzed in finer detail to determine eruption rates, which are critical for connecting volcanism, associated volatile emissions, and any potential effects on the Earth's climate before and after the Cretaceous–Paleogene boundary (KPB). It is our observation that the community has frequently misinterpreted how the eruption rates derived from these two datasets vary across the KPB. The U−Pb dataset of Schoene et al. (2019) was interpreted by those authors to indicate four major eruptive pulses before and after the KPB. The 40Ar/39Ar dataset did not identify such pulses and has been largely interpreted by the community to indicate an increase in eruption rates coincident with the Chicxulub impact (Renne et al., 2015; Richards et al., 2015). Although the overall agreement in eruption duration is an achievement for geochronology, it is important to clarify the limitations in comparing the two datasets and to highlight paths toward achieving higher-resolution eruption models for the Deccan Traps and for other large igneous provinces. Here, we generate chronostratigraphic models for both datasets using the same statistical techniques and show that the two datasets agree very well. More specifically, we infer that (1) age modeling of the 40Ar/39Ar dataset results in constant eruption rates with relatively large uncertainties through the duration of the Deccan Traps eruptions and provides no support for (or evidence against) the pulses identified by the U−Pb data, (2) the stratigraphic positions of the Chicxulub impact using the 40Ar/39Ar and U−Pb datasets do not agree within their uncertainties, and (3) neither dataset supports the notion of an increase in eruption rate as a result of the Chicxulub impact. We then discuss the importance of systematic uncertainties between the dating methods that challenge direct comparisons between them, and we highlight the geologic uncertainties, such as regional stratigraphic correlations, that need to be tested to ensure the accuracy of eruption models. While the production of precise and accurate geochronologic data is of course essential to studies of Earth history, our analysis underscores that the accuracy of a final result is also critically dependent on how such data are interpreted and presented to the broader community of geoscientists.
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用地质年代学资料评价德干圈闭喷发速率
摘要最近建立德干圈闭大火成岩省喷发历史的尝试使用了U - Pb (Schoene等人,2019)和40ar /39Ar (Sprain等人,2019)地质年代学。这两项研究都以高精度和前所未有的覆盖范围报告了一个大火成岩省的日期,并同意喷发的主要阶段开始于C30n-C29r磁极反转附近,并在c29r - c29n磁极反转后不久减弱,持续时间总计约700-800 kyr。可以对这些数据集进行更详细的分析,以确定喷发速率,这对于连接火山活动、相关的挥发性排放物以及白垩纪-古近纪边界(KPB)前后对地球气候的任何潜在影响至关重要。根据我们的观察,社区经常误解从这两个数据集得出的喷发率在KPB上的差异。Schoene等人(2019)的U - Pb数据集被这些作者解释为表明了KPB前后的四个主要喷发脉冲。40Ar/39Ar数据集没有识别出这样的脉冲,并且在很大程度上被社区解释为表明与希克苏鲁伯撞击同时爆发率增加(Renne et al., 2015;Richards et al., 2015)。虽然火山喷发持续时间的总体一致是地质年代学的一项成就,但重要的是要澄清比较两个数据集的局限性,并强调为德干圈闭和其他大型火成岩省实现更高分辨率火山喷发模型的途径。在这里,我们使用相同的统计技术为两个数据集生成了年代地层模型,并表明两个数据集非常吻合。更具体地说,我们推断(1)40Ar/39Ar数据集的年龄建模结果在德干圈闭喷发期间具有相对较大的不确定性的恒定喷发速率,并且不能支持(或反对)U - Pb数据确定的脉冲;(2)使用40Ar/39Ar和U - Pb数据集确定的希克苏鲁伯撞击的地层位置在其不确定性范围内不一致。(3)两个数据集都不支持希克苏鲁伯撞击导致喷发速率增加的观点。然后,我们讨论了挑战它们之间直接比较的测年方法之间系统不确定性的重要性,并强调了地质不确定性,例如区域地层相关性,需要进行测试以确保喷发模型的准确性。虽然精确和准确的地质年代学数据的产生对地球历史的研究当然是必不可少的,但我们的分析强调,最终结果的准确性也严重依赖于如何解释这些数据并将其呈现给更广泛的地球科学家群体。
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来源期刊
Geochronology
Geochronology Earth and Planetary Sciences-Paleontology
CiteScore
6.60
自引率
0.00%
发文量
35
审稿时长
19 weeks
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